JP3041850B2 - Portable communication terminal device, communication terminal docking station, and optical communication cable - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a portable communication terminal device such as a portable telephone device having an optical communication function, and an optical signal which accommodates the portable communication terminal device and transmits an optical signal to the portable communication terminal device. The present invention relates to a communication terminal docking station for transmitting and receiving, and an optical communication cable for connecting portable communication terminal devices.

[0002]

2. Description of the Related Art In a portable telephone device, in addition to a function of making a telephone call, telephone number data and a portable telephone device are transmitted by optical communication using infrared rays with another portable telephone device or a personal computer. Some devices have a function of transmitting and receiving program data to be controlled. Such a mobile phone device uses infrared rays of the same frequency for transmission and reception, and communicates by propagating the infrared rays into the air. In addition, an optical filter that selectively transmits infrared light is disposed close to and in front of the infrared light transmitting unit and the light receiving unit, and the filter blocks unnecessary external light.

[0003] Incidentally, the transmitted optical signal is not only received by a portable telephone device or the like of a communication partner, but also usually transmitted.
The light is reflected by a nearby object and is incident on its own light receiving unit. Therefore, half-duplex communication in which reception is stopped during transmission is performed. For example, when optical communication is performed between two mobile phone devices, it is possible to reduce the influence of the above-described reflection by arranging both the light transmitting unit and the light receiving unit close to each other. In such a case, reflection by a filter or a case member on the other side becomes a problem, and it is also difficult to simultaneously perform transmission and reception.

[0004]

As described above, since half-duplex communication has been conventionally performed, the amount of data transmission per unit time is half as compared with full-duplex communication in which transmission and reception are simultaneously performed. Communication took time and power consumption also increased. Furthermore, as described above, the effect of external light is reduced by the filter, but in the case of strong external light such as sunlight, a transmission error is likely to occur due to the influence, and the data transmission efficiency is reduced. In some cases, communication took longer due to the decrease. This problem can be solved, for example, by connecting the mobile phone devices using an electrical cable, for example, but when the electrical connection is made, a contact failure due to aging occurs in the connector portion, Alternatively, there is a problem that water may cause a short circuit or a leak.

Accordingly, an object of the present invention is to provide a portable communication terminal device capable of full-duplex communication and not affected by external light. It is an object of the present invention to provide a communication terminal docking station capable of connecting to a portable communication terminal device and an optical communication cable for connecting portable communication terminal devices.

[0006]

SUMMARY OF THE INVENTION In order to achieve the above object, the present invention provides a light transmitting unit and a light receiving unit which are juxtaposed to each other, and a light transmitting unit and a light receiving unit which are arranged in front of the light transmitting unit and the light receiving unit. An optical filter disposed therein, a light transmitting unit transmits an optical signal through the filter, and the light receiving unit receives an optical signal through the filter to perform optical communication. On the outer surface of the filter, one of a front portion of the light transmitting portion and the light receiving portion has a convex portion and the other has a concave portion. When optical communication is performed between two portable communication terminal devices according to the present invention, the two portable communication terminal devices are arranged so that respective filters face each other, and one portable communication terminal device is used. The convex and concave portions of the filter of the device are closely fitted to the concave and convex portions of the filter of the other portable communication terminal device, respectively. In such a state, the optical signal transmitted by the light transmitter of one portable communication terminal device is emitted through the convex portion of the filter on the own device side, and is directly received by the light receiving portion of the other device through the concave portion of the filter on the other device side. Incident on the part. Therefore, the transmitted optical signal is not reflected on the way and incident on the light receiving unit on the own device side, and the transmitted optical signal is received only by the light receiving unit on the partner device side.

The present invention also includes a light transmitting unit and a light receiving unit juxtaposed adjacent to each other, and an optical filter arranged in front of and close to the light transmitting unit and the light receiving unit. ,
Transmitting an optical signal from the light transmitting unit through the filter,
Optical communication is performed by receiving an optical signal through the filter by the light receiving unit, and a convex portion is formed on one of the light transmitting unit and the front portion of the light receiving unit on the surface of the filter. A communication terminal docking station for mounting a portable communication terminal device having a concave portion formed on one side, wherein a housing portion of the portable communication terminal device, and the portable communication terminal device housed in the housing portion. A second filter through which the optical signal transmitted by the light transmitting unit of the portable communication terminal device and the optical signal incident on the light receiving unit of the portable communication terminal device are transmitted. On the surface of the second filter, there is formed a second concave portion in which the convex portion of the filter is closely fitted and a second convex portion in which the concave portion of the filter is closely fitted. Be that And butterflies. When using the communication terminal docking station of the present invention, the portable communication terminal device is placed in the housing so that its filter faces the second filter. Thereby, the filter of the portable communication terminal abuts on the second filter of the communication terminal docking station, and the projection of the filter of the portable communication terminal is in close contact with the second recess of the second filter. The fit of the filter is such that the concave portion of the filter of the portable communication terminal device is closely fitted to the second convex portion of the second filter. Therefore,
The optical signal transmitted by the light transmitting unit of the portable communication terminal device exits through the convex portion of the filter and directly passes through the second concave portion of the second filter of the communication terminal docking station.
Incident on the light-receiving part of. The optical signal transmitted by the second light transmitting unit of the communication terminal docking station is emitted through the second convex portion of the second filter, and is directly incident on the light receiving unit through the concave portion of the filter of the portable communication terminal device. . Therefore, the optical signal transmitted from the mobile phone device is not reflected on the way and incident on the light receiving section of the mobile phone device, and the optical signal emitted from the second filter of the communication terminal docking station is also in the middle. Does not reflect back to the second filter of the communication terminal docking station.

The present invention also includes a light transmitting unit and a light receiving unit juxtaposed adjacent to each other, and an optical filter disposed in front of and close to the light transmitting unit and the light receiving unit. ,
Transmitting an optical signal from the light transmitting unit through the filter,
Optical communication is performed by receiving an optical signal through the filter by the light receiving unit, and a convex portion is formed on one of the light transmitting unit and the front portion of the light receiving unit on the surface of the filter. An optical communication cable interconnecting first and second portable communication terminal devices each having a recess formed therein, the cable including first and second optical fibers transmitting the optical signal; An optical communication connector made of a material through which the optical signal transmitted through the cable is transmitted, attached to both ends of the cable, and connected to a portable communication terminal device by adhering a surface to a surface of the filter; And a third recess on the surface of the optical communication connector, wherein the projection of the filter is tightly fitted when the optical communication connector is connected to the portable communication terminal device; And a third convex portion in which the concave portion of the filter is closely fitted to be fitted, and one end of the first optical fiber is provided inside the third convex portion of one of the optical communication connectors. And the other end is disposed inside the third recess of the other optical communication connector,
Both end portions of the second optical fiber are respectively arranged inside the third convex portion and the third concave portion different from the first optical fiber of each optical communication connector. I do. When using the optical communication cable of the present invention, the surface of each optical communication connector is brought into contact with the filter surface of the portable communication terminal device, and the third convex portion of the optical communication connector is placed in the concave portion of the filter. The third concave portions of the optical communication connector are fitted in close contact with the convex portions of the filter.
In this state, the optical signal transmitted by the light transmitting unit of one portable communication terminal device enters the third concave portion of one optical communication connector through the convex portion of the filter of the portable communication terminal device, and The opposite optical communication connector is reached through one of the first and second fibers. The optical signal that has reached the optical communication connector on the opposite side is emitted from the third convex portion of the optical communication connector, and is incident on the light receiving portion through the filter concave portion of the other portable communication terminal device. Therefore, when this optical communication cable is used, the optical signal transmitted by the light transmitting unit of the portable communication terminal device is directly transmitted from the third concave portion of the optical communication connector through the convex portion of the filter. It is incident on one of the optical fibers. Therefore, the transmitted optical signal is not reflected on the way and incident on the light receiving unit of the own device side, and the optical signal transmitted from the portable communication terminal device is transmitted from the third concave portion of the optical communication connector to the first and the second concave portions. Second
Incident on only one of the optical fibers.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, embodiments of the present invention will be described based on embodiments with reference to the drawings. FIG. 1 is a schematic plan view showing a portable telephone device as an example of a portable communication terminal device according to the present invention. The mobile phone device 2 has a function of transmitting and receiving telephone number data and the like to and from another mobile phone device by infrared optical communication in addition to a function of making a telephone call. As shown in FIG. 1, the mobile telephone device 2 includes an optical communication interface 4 for optical communication on the side, and the optical communication interface 4 includes a light emitting diode 6 arranged in close proximity to each other. It includes a light receiving section 12 composed of the light section 8 and the photodiode 10, and an optical filter 14 disposed in front of and close to the light transmitting section 8 and the light receiving section 12.

The light transmitting section 8 and the light receiving section 12 each transmit and receive an infrared light signal, and the filter 14 mainly transmits only infrared light. Then, the optical signal emitted from the light transmitting unit 8 is transmitted through the filter 14, while the optical signal from the communication partner enters the light receiving unit 12 through the filter 14,
Converted to electrical signals.

The portable telephone device 2 includes an infrared control circuit 16 and a CPU 18 (central processing unit), and data signals to be transmitted such as telephone number information are supplied from the CPU 18 to the infrared control circuit 16, The circuit 16 drives the light emitting diode 6 based on the data signal,
A light signal is transmitted by infrared rays. On the other hand, the electric signal generated by receiving the optical signal by the photodiode 10 is supplied to the infrared control circuit 16, which amplifies the electric signal, performs waveform shaping, etc., and supplies it to the CPU 18 as a data signal. .

On the outer surface of the filter 14, a projection 14A is formed at a location in front of the light transmitting section 8, while a recess 14B is formed at a location in front of the light receiving section 12. FIGS. 2A and 2B show two such configurations.
FIG. 4 is an explanatory diagram showing a case where optical communication is performed between two mobile phone devices 2. When optical communication is performed between two mobile phone devices 2, as shown in FIG. 2A, the two mobile phone devices 2 are arranged such that the respective optical communication interfaces 4 face each other. Then, as shown in FIG. 2B, the side portions of the mobile phone device 2 are brought into contact with each other, and the convex portion 14A and the concave portion 14B of the filter 14 of one mobile phone device 2 are connected to the other mobile phone device. Recess 1 of filter 14 of telephone device 2
4B and the protrusion 14A are fitted in close contact with each other.

In such a state, the optical signal transmitted by the light transmitting unit 8 (FIG. 1) of one of the portable telephone devices 2 is emitted through the convex portion 14A of the filter 14 of the own device, and directly transmitted to the other device. The light enters the light receiving unit 12 on the partner device side through the concave portion 14B of the filter 14. Therefore, the transmitted optical signal does not reflect on the way and enters the light receiving unit 12 of the own device, and the transmitted optical signal is received only by the light receiving unit 12 of the partner device.

Therefore, in the portable telephone device 2 of the present embodiment, the optical signal is transmitted from one portable telephone device 2 and at the same time, the other portable telephone device 2 performs the full-duplex communication in which the optical signal is also transmitted. It is possible. As a result, optical communication can be performed at twice the speed of the related art, and communication time and power consumption can be reduced. Further, since the light receiving unit 12 is covered by the side of the partner device, external light is
This does not cause a problem of adversely affecting the communication due to the incident light, and therefore the data transmission efficiency is improved. Therefore, the communication time can be shortened also in this respect. In this embodiment, the convex portion 14A is formed in front of the light transmitting portion 8 and the concave portion 14B is formed in front of the light receiving portion 12. However, a concave portion is formed in front of the light transmitting portion 8. Of course, it is of course possible to adopt a configuration in which a front convex portion of the light receiving section 12 is formed.

As shown in FIG. 1, it is effective to provide the optical communication interface 4 with a switch 20 for identifying the type of the optical communication interface 4 of the partner device. The switch 20 has a movable portion 22, and the tip of the movable portion 22 protrudes into the concave portion 14 </ b> B of the filter 14. The switch 20 is electrically connected to the CPU 18,
The PU 18 can detect opening and closing of the switch 20.

In such a configuration, if the partner device is the portable telephone device 2 according to the present invention, the switch 20
Of the filter 14 of the counterpart device.
The switch 20 is pressed and displaced, and the open / close state of the switch 20 changes. The CPU 18 detects this and can determine that the partner device is the mobile phone device 2 according to the present invention, and in that case, the CPU 18 performs full-duplex communication with the partner device. On the other hand, when the partner device is not the mobile phone device 2 according to the present invention, the movable portion 22 of the switch 20 is not pressed and does not move, so that the open / close state of the switch 20 does not change. Therefore, the CPU 18 can determine that the partner device is not the mobile phone device 2 according to the present invention,
In this case, the CPU 18 performs half-duplex communication with the counterpart device as in the related art. As described above, when the switch 20 is provided, it is possible to automatically identify whether or not the partner device is the mobile phone device 2 according to the present invention and switch between full-duplex communication and half-duplex communication. Yes, the user does not need to perform the switching operation.

In this embodiment, the case where the present invention is applied to the portable telephone device 2 has been described as an example. However, the present invention is not limited to the portable telephone device, but can be applied to various portable communication terminal devices.
For example, a PD having a telephone function and a computer function
A (Personal digital Assista)
nts) and devices referred to as mobile terminals.

Next, an example of the communication terminal docking station according to the present invention will be described. FIG. 3 is a plan view showing an example of the communication terminal docking station according to the present invention, and FIG. 4 is a perspective view for explaining how to use the communication terminal docking station of FIG. In FIG. 4, FIG.
The same elements as those described above are denoted by the same reference numerals. This communication terminal docking station 24 is for mounting the above-mentioned mobile phone device 2,
6 and a second optical communication interface 28 provided at a location facing the filter 14 of the mobile phone device 2 housed in the housing section 26, and the second optical communication interface 28 The second filter 14 is in close contact with the second optical filter and transmits the optical signal transmitted by the light transmitting unit 8 (FIG. 1) of the mobile phone device 2 and the optical signal incident on the light receiving unit 12 of the mobile phone device 2. 30 and the second
On the surface of the filter 30 of FIG.
The second concave portion 30B in which the filter 14
And the second convex portion 30A, into which the concave portion 14B is closely fitted.

Further, the second optical communication interface 2
8, a second light transmitting unit 3 including a light emitting diode for transmitting an optical signal to the light receiving unit 12 of the mobile phone device 2 through a second filter 30 based on an externally supplied electric signal.
2 and a second light receiving unit 34 including a photodiode that receives an optical signal from the light transmitting unit 8 of the mobile phone device 2 through the second filter 30 and generates an electric signal. In addition, the communication terminal docking station 24
A communication cable 31 is provided as input / output means for inputting an electric signal to be transmitted by the second light transmitting unit 32 and outputting the electric signal generated by the second light receiving unit 34.

When using the communication terminal docking station 24 configured as described above, as shown in FIG. 4, the portable telephone device 2 is moved so that its optical communication interface 4 faces the second optical communication interface 28. And placed in the accommodation section 26. As a result, the mobile phone device 2 is fixed in the housing 26, and the filter 14 of the mobile phone device 2 is connected to the second terminal of the communication terminal docking station 24.
And the convex portion 14A of the filter 14 of the mobile phone device 2 is fitted in close contact with the second concave portion 30B of the second filter 30, and the concave portion 14B of the filter 14 of the mobile phone device 2 Is fitted in close contact with the second projection 30A of the second filter 30.

Therefore, the light transmitting section 8 of the portable telephone device 2
The optical signal transmitted by (FIG. 1) is a projection 14A of the filter 14.
Through the second concave portion 30B (FIG. 3) of the second filter 30 of the communication terminal docking station 24, and directly enters the second light receiving portion. The optical signal transmitted by the second light transmitting section 32 of the communication terminal docking station 24 is transmitted to the second convex section 30 of the second filter 30.
A is emitted through A and directly to the filter 1 of the mobile phone device 2.
The light enters the light receiving unit 12 through the four concave portions 14B.

Therefore, when the communication terminal docking station 24 of this embodiment is used, full-duplex communication is performed between the communication terminal docking station 24 and the portable telephone device 2 as in the case of the above embodiment. Is possible,
When communication is performed between, for example, a computer and the mobile phone device 2 connected via the communication cable 31, communication time and power consumption can be reduced. Further, since the filter 14 and the second filter 30 are in close contact with each other, there is no problem that external light enters the light receiving section 12 and the second light receiving section 34 and adversely affects communication. Since the efficiency is improved, the communication time can be reduced in this respect as well.

This communication terminal docking station 24
Can be applied in various ways, and FIGS. 5 and 6 show application examples.
FIG. 5 is a configuration diagram showing a case where the communication terminal docking station 24 is connected to a computer, and FIG. 6 is a configuration diagram showing a case where the communication terminal docking station 24 is connected to a car navigation system.

The communication terminal docking station 36 shown in FIG. 5 is for a PDA, and a PDA 37 having the same type of optical communication interface as the optical communication interface 4 of the portable telephone device 2 is accommodated in the accommodation section 26. Thus, efficient communication can be performed between the PDA 37 and the personal computer 38. On the other hand, the communication terminal docking station 24 shown in FIG.
Of the mobile phone device 2 and the car navigation system 23 can be efficiently communicated. For example, when the mobile phone device 2 is connected to a network server, Data communication with the network server becomes possible.

The communication terminal docking station 2
4, the second optical communication interface 28 is configured to include the second light transmitting unit 32 and the second light receiving unit 34. Instead of using these light transmitting unit and light receiving unit, the communication cable 31 is connected. The optical communication cable is made of an optical fiber, and the end of the optical communication cable is replaced with the second projection 30A of the second filter 30.
In addition, it is also effective to adopt a configuration in which it is arranged inside the second concave portion 30B. In this case, the communication terminal docking station 24 is connected to a personal computer or the like by an optical communication cable, and optical communication can be performed between the mobile phone device 2 and the personal computer without using an electric signal.

Next, an example of the optical communication cable according to the present invention will be described. FIG. 7 is a configuration diagram showing an example of the optical communication cable according to the present invention. In the figure, the same elements as those in FIG. 1 are denoted by the same reference numerals. The optical communication cable 40 is for connecting two portable telephone devices 2 as shown in FIG. 7, for example, and includes first and second optical fibers 42 and 44 for transmitting an optical signal. 4
6 and a material through which an optical signal transmitted through the cable 46 is transmitted. The optical communication connector 48 is attached to both ends of the cable 46 and is connected to the cellular phone device 2 with its surface in close contact with the surface of the filter 14. And

Then, on the surface of the optical communication connector 48,
When the optical communication connector 48 is connected to the mobile phone device 2, a third concave portion 48B in which the convex portion 14A of the filter 14 fits closely and a third convex portion in which the concave portion 14B of the filter 14 fits closely. 48A are formed. One end of the first optical fiber 42 is connected to one optical communication connector 4.
8 is disposed inside the third convex portion 48A, and the other end of the third concave portion 48B of the other optical communication connector 48 is provided.
, And both ends of the second optical fiber 44 are respectively connected to the first optical fiber 42 of each optical communication connector 48.
Are arranged inside the third convex portion 48A and the third concave portion 48B which are different from those of FIG.

When this optical communication cable 40 is used, the surface of each optical communication connector 48 is brought into contact with the surface of the filter 14 of the optical communication interface 4 of the portable telephone device 2, and Of the filter 14 and the third recess 48B of the optical communication connector 48 in close contact with the projection 14A of the filter 14, respectively. In this state, the optical signal transmitted by the light transmitting unit 8 (FIG. 1) of one mobile phone device 2 passes through the convex portion 14A of the filter 14 of the mobile phone device 2 and the third concave portion of one optical communication connector 48. 48B and arrives at the opposite optical communication connector 48 through one of the first and second optical fibers 42,44. The optical signal that has reached the optical communication connector 48 on the opposite side is emitted from the second convex portion 48A of the optical communication connector 48 and enters the light receiving portion 12 through the concave portion 14B of the filter 14 of the other mobile phone device 2. .

Therefore, when the optical communication cable 40 is used, the optical signal transmitted by the light transmitting section 8 of the portable telephone device 2 is directly transmitted through the convex section 14A of the filter 14 to the third concave section of the optical communication connector 48. The light enters one of the first and second optical fibers 42 and 44 from 48B. For this reason, the transmitted optical signal is reflected on the way, and
, And the optical signal transmitted from the mobile phone device 2 enters only one of the first and second optical fibers 42 and 44 from the third concave portion 48B of the optical communication connector 48.

As a result, when this optical communication cable 40 is used, full-duplex communication in which an optical signal is transmitted from one portable telephone device 2 and the other portable telephone device 2 is also transmitted simultaneously. It is possible to do. As a result, optical communication can be performed at twice the speed of the related art, and communication time and power consumption can be reduced. Further, since the light receiving section 12 of the mobile phone device 2 is covered with the optical communication connector 48, the problem that external light enters the light receiving section 12 and adversely affects communication does not occur. Therefore, data transmission efficiency is improved. In this respect, the communication time can be reduced.

[0031]

As described above, when optical communication is performed between two portable communication terminals according to the present invention, the two portable communication terminals are arranged so that their filters face each other. Then, the convex and concave portions of the filter of one portable communication terminal device are fitted in close contact with the concave and convex portions of the filter of the other portable communication terminal device, respectively. In such a state, the optical signal transmitted by the light transmitter of one portable communication terminal device is emitted through the convex portion of the filter on the own device side, and is directly received by the light receiving portion of the other device through the concave portion of the filter on the other device side. Incident on the part. Therefore, the transmitted optical signal is not reflected on the way and incident on the light receiving unit on the own device side, and the transmitted optical signal is received only by the light receiving unit on the partner device side. Therefore, in the portable communication terminal device of the present invention, it is possible to perform full-duplex communication in which one portable communication terminal device transmits an optical signal and the other portable communication terminal device simultaneously transmits an optical signal. It is. As a result, optical communication can be performed at twice the speed of the related art, and communication time and power consumption can be reduced. Further, since the light receiving unit is covered by the side of the partner device, there is no problem that external light is incident on the light receiving unit and adversely affects the communication. Therefore, the data transmission efficiency is improved. You can save time.

When using the communication terminal docking station of the present invention, the portable communication terminal device is placed in the housing so that its filter faces the second filter. Thereby, the filter of the portable communication terminal abuts on the second filter of the communication terminal docking station, and the projection of the filter of the portable communication terminal is in close contact with the second recess of the second filter. The fit of the filter is such that the concave portion of the filter of the portable communication terminal device is closely fitted to the second convex portion of the second filter. Therefore, the optical signal transmitted by the light transmitting unit of the portable communication terminal device exits through the convex portion of the filter, and directly enters the second light receiving unit through the second concave portion of the second filter of the communication terminal docking station. . The optical signal transmitted by the second light transmitting unit of the communication terminal docking station is emitted through the second convex portion of the second filter, and is directly incident on the light receiving unit through the concave portion of the filter of the portable communication terminal device. . Therefore, the optical signal transmitted from the mobile phone device is not reflected on the way and incident on the light receiving section of the mobile phone device, and the optical signal emitted from the second filter of the communication terminal docking station is also in the middle. Does not reflect back to the second filter of the communication terminal docking station. As a result, when the communication terminal docking station of the present invention is used, full-duplex communication can be performed between the communication terminal docking station and the portable communication terminal device. When communication is performed between a computer or the like and a portable communication terminal device, a reduction in communication time and a reduction in power consumption can be realized. Further, since the filter and the second filter are in close contact with each other,
The problem that external light enters the light receiving unit and the second light receiving unit and adversely affects communication does not occur. Therefore, data transmission efficiency is improved, so that the communication time can be shortened also in this respect.

When using the optical communication cable of the present invention, the surface of each optical communication connector is brought into contact with the filter surface of the portable communication terminal device, and the third optical communication connector is used.
And the third concave portion of the optical communication connector are fitted in close contact with the concave portions of the filter, respectively. In this state, the optical signal transmitted by the light transmitting unit of one portable communication terminal device enters the third concave portion of one optical communication connector through the convex portion of the filter of the portable communication terminal device,
Then, it reaches the optical communication connector on the opposite side through one of the first and second fibers. The optical signal arriving at the opposite optical communication connector is transmitted to the third optical communication connector.
The light exits from the convex portion and enters the light receiving portion through the filter concave portion of the other portable communication terminal device. Therefore, when the optical communication cable is used, the optical signal transmitted by the light transmitting unit of the portable communication terminal device is directly transmitted from the third concave portion of the optical communication connector through the convex portion of the filter.
To one of the optical fibers. Therefore, the transmitted optical signal is not reflected on the way and incident on the light receiving unit of the own device side, and the optical signal transmitted from the portable communication terminal device is transmitted from the third concave portion of the optical communication connector to the first and the second concave portions. The light enters only one of the second optical fibers. As a result, when this optical communication cable is used, full-duplex communication in which one portable communication terminal device transmits an optical signal and the other portable communication terminal device simultaneously transmits an optical signal is performed. Is possible. As a result, optical communication can be performed at twice the speed of the related art, and communication time and power consumption can be reduced. Further, since the light receiving portion of the portable communication terminal device is covered with the optical communication connector, the problem that external light enters the light receiving portion and adversely affects communication does not occur. Therefore, data transmission efficiency is improved. The communication time can also be reduced in terms of points.

[Brief description of the drawings]

FIG. 1 is a schematic plan view showing a mobile phone device as an example of a mobile communication terminal device according to the present invention.

FIGS. 2A and 2B are explanatory diagrams showing a case where optical communication is performed between two portable telephone devices having such a configuration.

FIG. 3 is a plan view showing an example of a communication terminal docking station according to the present invention.

FIG. 4 is a perspective view illustrating how to use the communication terminal docking station of FIG. 3;

FIG. 5 is a configuration diagram showing a case where a communication terminal docking station is connected to a computer.

FIG. 6 is a configuration diagram showing a case where a communication terminal docking station is connected to a car navigation system.

FIG. 7 is a configuration diagram illustrating an example of an optical communication cable according to the present invention.

[Explanation of symbols]

2 ... mobile phone device, 4 ... optical communication interface,
6 light emitting diode, 8 light transmitting unit, 10 photodiode, 12 light receiving unit, 14 filter, 14
A: convex portion, 14B: concave portion, 16: infrared control circuit, 18: CPU, 20: switch, 22: movable portion, 24: communication terminal docking station, 26:
... accommodation part, 28 ... second optical communication interface, 3
0: second filter, 30A: second convex portion, 30B
... Second concave portion, 32 second light transmitting portion, 34 second
, A light-receiving part of the communication terminal docking station,
38 personal computer, 40 optical communication cable, 42 first optical fiber, 44 second optical fiber, 46 cable, 48 optical communication connector,
48A... Third convex portion, 48B... Third concave portion.

──────────────────────────────────────────────────続 き Continuation of front page (58) Field surveyed (Int. Cl. ⁷ , DB name) H04B 10/00 G06F 3/00

Claims (11)

(57) [Claims] A light transmitting unit and a light receiving unit that are juxtaposed to each other and an optical filter that is disposed in front of and close to the light transmitting unit and the light receiving unit; In a portable communication terminal device that performs optical communication by transmitting an optical signal from the optical unit through the filter and receiving the optical signal through the filter by the light receiving unit, the outer surface of the filter includes the light transmitting unit and the light transmitting unit. A portable communication terminal device, wherein a convex portion is formed on one side and a concave portion is formed on the other side in front of the light receiving section. 2. The portable communication terminal device according to claim 1, wherein said optical signal is infrared light. 3. The portable communication terminal device according to claim 2, wherein the filter mainly selectively transmits infrared light. 4. The portable communication terminal device according to claim 1, wherein said light transmitting unit is constituted by a light emitting diode. 5. The portable communication terminal device according to claim 1, wherein said light receiving section is constituted by a photodiode. 6. The portable communication terminal device according to claim 1, further comprising a switch that moves and opens and closes the movable portion, wherein the movable portion is disposed in the concave portion of the filter. 7. The portable communication terminal device according to claim 1, wherein the portable communication terminal device is a portable telephone device. 8. The portable communication terminal device according to claim 1, further comprising a telephone function and a computer function. 9. A light transmitting unit, comprising: a light transmitting unit and a light receiving unit juxtaposed adjacent to each other; and an optical filter disposed in front of and close to the light transmitting unit and the light receiving unit. An optical signal is transmitted from the optical unit through the filter, and optical communication is performed by receiving the optical signal through the filter by the light receiving unit. On the surface of the filter, a location in front of the light transmitting unit and the light receiving unit. A communication terminal docking station for mounting a portable communication terminal device in which a convex portion is formed on one side and a concave portion is formed on the other side, wherein an accommodating portion of the portable communication terminal device; The filter of the portable communication terminal device accommodated in the filter is in close contact with the light signal transmitted by the light transmitting unit of the portable communication terminal device and the light incident on the light receiving unit of the portable communication terminal device. signal A second filter through which a convex portion of the filter fits in close contact with a surface of the second filter, and a second concave portion in which a concave portion of the filter fits in close contact with the surface of the second filter. 2. A communication terminal docking station, comprising: two projections. 10. A second light transmitting unit for transmitting the optical signal to the light receiving unit of the portable communication terminal device through the second filter based on an electric signal supplied from outside, and the second filter. A second light receiving unit that receives the optical signal from the light transmitting unit of the portable communication terminal device and generates an electric signal, and inputs the electric signal to be transmitted by the second light transmitting unit The communication terminal docking station according to claim 9, further comprising: an input / output unit that outputs the electric signal generated by the first light receiving unit. 11. A light transmitting unit, comprising: a light transmitting unit and a light receiving unit juxtaposed to each other and an optical filter disposed in front of and close to the light transmitting unit and the light receiving unit. An optical signal is transmitted from the optical unit through the filter, and optical communication is performed by receiving the optical signal through the filter by the light receiving unit. On the surface of the filter, a location in front of the light transmitting unit and the light receiving unit. An optical communication cable interconnecting the first and second portable communication terminal devices, each having a convex portion formed on one side and a concave portion formed on the other side, wherein the optical communication cable transmits the optical signal; A cable including first and second optical fibers; and a material through which the optical signal transmitted through the cable is transmitted. The cable is attached to both ends of the cable, and the surface is brought into close contact with the surface of the filter. An optical communication connector connected to a communication terminal device, wherein the projection of the filter is fitted and fitted on the surface of the optical communication connector when the optical communication connector is connected to the portable communication terminal device. And a third convex portion in which the concave portion of the filter fits in close contact with the filter, and one end of the first optical fiber is connected to the third convex portion of one of the optical communication connectors. 3, the other end is disposed inside the third concave portion of the other optical communication connector, and both ends of the second optical fiber are each optical communication connector. An optical communication cable, wherein the optical communication cable is arranged inside the third convex portion and the third concave portion different from the first optical fiber.